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Transcript
73
Journal of Scientific Research
Banaras Hindu University, Varanasi
Vol. 56, 2012 : 73-79
ISSN : 0447-9483
ELIMINATION OF MUTANT TYPES IN SELECTION
EXPERIMENT BETWEEN WILD TYPE
AND MUTANT EYE COLOUR IN
DROSOPHILA ANANASSAE
A. K. Singh
Genetics Laboratory, Department of Zoology,
Banaras Hindu University, Varanasi-221005, India
E-mail: [email protected]
Abstract
Equal number of males and females of wild type and ruby eye colour mutant
flies of Drosophila ananassae were cultured and the progeny derived from such
cross were transferred to successive generations until the numbers of mutant
flies completely disappear from the population. Comparison of gene frequencies
between wild males and mutant males were made and it was found that ruby
eyed flies of both sexes completely disappeared in F9.
Keywords: Drosophila, wild type and mutant flies, natural selection.
Introduction
Organisms with phenotypes that are better suited to the environment have a better
probability of surviving the struggle and will leave more offspring. Presumably, the
better an organism can see, the better chance it has of locating food, defending itself,
finding mates and so on and the greater will be its chance of survival and reproduction.
Darwin called the process of differential survival and reproduction of different types as
natural selection by analogy with the artificial selection carried out by animal and plant
breeders, when they deliberately select some individuals of a preferred type. The relative
probability of survival and rate of reproduction of a phenotype or genotype is now called
its Darwinian fitness. In fact the concept of fitness really applies to the average survival
and reproduction of individuals in a phenotypic or genotypic class. The concept of
natural selection provides a frame work for explaining how allele frequencies are
maintained in the populations; it also explains how species become adapted to the
environments in which they live. One can observe several species in their native
environments, and in some cases, it seems obvious how certain characteristics provide an
organism with a survival advantage.
74
A. K. SINGH
Genetic variations occur in all the organisms. Natural selection is a creative force in
the process of evolution since it favours and encourages efficient genes and gene
combinations. The phenomenon of natural selection has been demonstrated in artificial
population containing chromosomal or genetic variants. Selection operates in only one
direction, towards the elimination of deleterious alleles and fixation of favourable alleles
(Strickberger, 1976). However, when the heterozygotes have higher Darwinian fitness to
the corresponding homozygotes, an equilibrium is established due to selection and both
the alleles will remain in the population.
Besides morphological variations, a number of chromosomal features for example
chromosomal polymorphism have been taken into consideration to study natural selection
in different species of Drosophila. In Drosophila it has been demonstrated that
chromosomal polymorphism is adaptive and balanced due to adaptive superiority of
heterozygotes (Dobzhansky, 1970). Drosophila melanogaster has extensively been used
to study the effect of natural selection on different mutant genes located on sex
chromosome or autosomes. It has been observed that the frequency of various sex-linked
genes and autosomal mutant genes decline rapidly (Heritier and Teissier 1937, Merrell,
1953: Reed and Reed, 1950). Reed and Reed (1950) performed selection experiments
using wild type and white eyed D. melanogaster and they reported that white eye gene
was eliminated from population in 25 generations. This was caused due to an inefficiency
of white eye males in mating. Chatterjee and Singh (1986) also conducted similar
experiments in D. ananassae and found that white eyed flies do not appear after sixth
generation. They suggested that various components of fitness such as sexual activity,
fecundity and viability acting in combination might have caused very quick elimination
of mutant gene from the laboratory populations.
Singh, Chatterjee and Roy (1985) studied mating behaviour of white eyed and wild
type D. ananassae and their results indicated that white eyed males were less successful
in mating as compared to wild type males. In the present experiment normal eyed and
mutant type (ruby eye colour) flies of D. ananassae were cultured in the same food
bottles and were reared for some generations to see whether the eye colour mutation
show a deleterious effect on the survival of these types.
Materials and Methods
In our laboratory different strains of wild type Drosophila ananassae and mutant
stocks are being cultured. In this study one of the wild type stocks derived from the mass
culture of Varanasi and a mutant stock having ruby eye colour were employed. The gene
causing ruby eye colour is situated on the X-chromosome and shows sex linked pattern of
inheritance. Virgin females and males from both the stocks were collected and aged for
five days. Equal number of males and females of both the stocks (5 wild females and 5
wild males; 5 ruby females and 5 ruby males) were cultured in individual food bottles. In
each generation when all the flies hatched in the bottle, they were sorted out into different
phenotypes in respect to their sex and counted. All the flies were then mixed and
transferred to fresh culture bottles. This was continued for several generations and the
WILD TYPE & MUTANT EYE COLOUR IN DROSOPHILA ANANASSAE
75
experiment was considered to be over when the mutant flies of both the sexes did not
appear in two successive generations.
Results
In this experiment two stocks were utilized, one mutant stock which is being reared
in our laboratory for several years and the other wild type stock which was established
from the flies collected from Varanasi. Virgin females and males from both the stocks
were collected and put in the separate vials for five days. On sixth day equal numbers of
males and females of both the stocks (wild 5 females + wild 5 males + ruby 5 females + 5
ruby males) were kept in food bottles. This experiment was done in replicate and the
data were pooled to calculate the gene frequency. Since this experiment was initiated by
culturing equal number of wild type and mutant flies, the frequency of both the alleles at
beginning was equal i.e. 50 percent each. In subsequent generations the the gene
frequency was estimated on the basis of data by following the method suggested by
Strickberger (1976).
Table 1 shows the number of wild type (red eyed) and mutant type (ruby eyed) flies
in different generations of Drosophila ananassae. Male and female flies with red and
ruby eye colour were recorded for ten generations. It was found that all four types of flies
appeared up to eight generations. The mutant females and males completely disappeared
in the ninth generation. When flies scored in ninth generation were cultured for one more
generation, it was found that none of the mutant type of either sex appeared in the next
generation.
Table1
Number of wild type (red eyed) and mutant type (ruby eyed) flies in different
generations of Drosophila ananassae.
Generation
Red eyed
female
Ruby eyed
female
Red eyed
male
Ruby eyed
male
Total
I
511
397
478
358
1744
II
495
143
465
220
1323
III
402
138
689
127
1356
IV
644
96
984
139
1863
V
613
44
696
28
1381
VI
393
22
764
32
1211
VII
512
38
432
12
994
VIII
446
06
623
07
1082
IX
426
00
642
00
1068
X
618
00
509
00
1127
76
A. K. SINGH
Table 2
Number of mutant males and the frequency of ruby eye gene in ten generations in
competition experiment in Drosophila ananassae
Generation
I
II
III
IV
V
VI
VII
VIII
IX
X
Total male flies
836
685
816
1123
724
796
444
630
642
509
Ruby allele (rb) frequency
42.6
32.1
15.6
12.4
3.9
4.02
2.7
1.1
0.0
0.0
Table 2 shows number of mutant males and the frequency of ruby eye gene in ten
generations in competition experiment in Drosophila ananassae. In this table only males
of two different phenotypes are being compared because genotype of only male
individuals could be ascertained. Red eyed females cannot be compared with their
respective types as they could also be carrier for the rb allele. It is clearly seen that the
frequency of rb allele declines in subsequent generations (except in sixth generation
when a slight increase was recorded), and the frequency of mutant type becomes nil in
the ninth generation.
Figure 1
Frequency of ruby eye allele in different generations of selection
experiments in D. ananassae.
frequency(%) of ruby eye gene
changes in the frequency of ruby eye gene in selection
experiment
45
40
35
30
25
20
15
10
5
0
1
2
3
4
5
6
7
Generations
8
9
10
11
WILD TYPE & MUTANT EYE COLOUR IN DROSOPHILA ANANASSAE
77
The change in the frequency of ruby gene is depicted in Fig.1. There is steady
decrease in the frequency of rb allele in further generation and complete elimination of
this mutant allele is witnessed in ninth generation.
Discussion
Natural selection results from the cumulative action of all forces tending to ensure
that individuals possessing one genetic constitution shall leave larger numbers of
offspring than will individuals possessing some other genetic constitution. Thus if a
mutation contributes in any way to the leaving of larger numbers of offspring it will be
perpetuated in increased proportion in the next generation since it will be carried by those
“larger number of offspring”. In case if the mutation interferes in any way with the
leaving of larger number of offspring it will be perpetuated in decreased proportion in the
next generation since it will be carried by but a decreased number of individuals in that
generation.
Natural selection experiments have been performed in different species of
Drosophila including Drosophila melanogaster by taking genetically determined traits.
For this purpose various autosomal and sex-linked genes have been utilised. The results
obtained indicate that the frequencies of mutant types declined rapidly in subsequent
generations (Hertier and Teissier 1934, Merrell 1953, Reed and Reed 1950). Experiments
in several species of Drosophila have also indicated that wild type males are more
successful in mating than mutant types. Therefore mutant genes have been found to
diminish mating activity in males of Drosophila (Reed and Reed 1950, Merrell 1953,
Petit 1951, Bastock 1956, Elens 1957). Reed and Reed (1950) performed experiment
involving wild type and white eye mutants in Drosophila melanogaster and observed
quick decline of mutant flies from subsequent generations. They suggested that the
elimination of white eye gene in about twenty five generations was caused due to
inefficiency of white males in mating. They also observed that for every 100 mating of
red males only 75 white males succeeded in D. melanogaster.
Singh, Chatterjee and Roy (1985) analyzed mating behaviour of white eyed and wild
type D. ananassae and their results indicated that white eyed males are less successful in
mating as compared to wild type males. Effect of light and dark on mating behavior of
red eye and white eye Drosophila ananassae was studied by Chatterjee and Singh(1988)
and their results suggest that white eye males are not successful in mating whereas red
eye males readily mate with both the types of females i.e. red eyed females and white
eyed females. They could also know that white eye males are more successful in mating
in dark than in light conditions and a significant decrease in mating success of red eye
males in dark was also found which is likely to be due to their lowered locomotor activity
indicating the importance of visual clues during courtship behavior in this species.
Chatterjee and Singh (1986) conducted competition experiments to study the effect
of selection on white eye gene in D. ananassae and found that white eye gene was
eliminated from the laboratory population in F7. Their experiments on mating propensity
78
A. K. SINGH
and selection clearly indicated that the rapid elimination of white eye gene in D.
ananassae is due to reduced sexual activity of white eye males combined with other
components of fitness such as fecundity and viability.
This experiment was conducted to see the persistence of mutant gene which causes
ruby eye colour along with wild type flies. Although ruby eye colour mutants provide
good culture and show normal fecundity when only mutants are being cultured but their
presence with wild type flies do affect their chances of mating and survival. The present
results of competition experiments in Drosophila ananassae show that the ruby gene was
completely eliminated from the population in ninth generation. In ninth and tenth
generation only wild type flies of both sexes were present in the population. Thus
selection favours wild type gene. It confers adaptive values to those which bear such
gene. Singh, Chatterjee and Roy studied mating behaviour between white eye and wild
type flies of D. ananassae and have shown that white eye gene diminishes the sexual
activity of males. The wild males were nearly two times more successful than white
males in mating, when females were exposed to males for six hours. Ruby eye mutants in
D. ananassae have not been involved for their effect on mating behaviour but the results
of this study give a clear hint that male individuals possessing ruby allele show lesser
mating success than their normal eye counterparts and that is the prime reason that their
number dwindles very fast in subsequent generations.
Acknowledgement
I am thankful to Ms Punita Nanda for her help during the observation of the flies.
REFERENCES
Bastock. M. (1956):
pp. 421-439.
A gene mutation that changes a behavior pattern. Evolution, 10:
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its wild type allele in Drosophila ananassae. Ind. J. Exp. Biol., 24: pp. 195-196.
Chatterjee, S. and Singh, B. N. (1988): Effect of light and dark on mating behavior of red eye
and white eye Drosophila ananassae. Ind. J. Exp. Biol., 26: pp. 611-614.
Dobzhansky, Th. (1970): Genetics of the evolutionary process (Columbia University Press,
New York)
Elens, A. A. (1957): Importance selective des differences d’ activite antire males ebony et
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WILD TYPE & MUTANT EYE COLOUR IN DROSOPHILA ANANASSAE
79
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